KR102203574B1 - supporting member for loading solar cell module - Google Patents

Abstract

In a preferred embodiment, the supporting member for mounting the solar cell module includes a panel portion supporting the edge of the solar cell module, and protruding upward from the panel portion in a'L' shape to form a wall. An upper support part having a coupling groove, a lower support part protruding downward from the panel part to form a wall like the upper support part, and having a protrusion placed in the coupling groove, and the panel part facing the lower support part It includes a facing portion forming a guide groove in the shape of a'ㄱ' from the bottom.

Description

Supporting member for loading solar cell module

The present invention relates to a support member used to horizontally load a solar cell module.

A solar cell module refers to a structure in which a plurality of solar cells are packaged with a sealing material between two substrates, and a frame made of aluminum surrounds them.

In order to transport the solar cell module, it must be packaged, and a support member is used to support the solar cell module and the module when horizontally loaded.

By the way. The weight of one solar cell module is generally around 20kg, and when these are stacked and packaged, problems such as damage during transport may occur because the support member cannot overcome the load.

In addition, since the solar cell module weighs 20 kg per sheet, the solar cell module must be installed at four corners of the solar cell module during packaging, or be easily fastened or disassembled when disassembling it to increase work efficiency.

The present invention is invented from the above technical background, and is to provide a support member for mounting a solar cell module that improves the above-described problems.

In a preferred embodiment, the support member includes a panel portion supporting the edge of the solar cell module, a wall protruding upward from the panel portion to form a wall, and a coupling groove made by cutting a portion An upper support part, a lower support part protruding downward from the panel part to form a wall like the upper support part, and having a protruding part placed in the coupling groove, and a'b' under the panel part facing the lower support part. It includes a facing portion forming a shaped guide groove.

It is preferable that the depth of the coupling groove and the height of the protrusion are the same.

The facing portion further includes a latch coupled to the frame of the solar cell module in the form of a latch, and the latch is formed at an end of the facing portion.

The solar cell module further includes a protrusion protruding from the facing portion toward the lower support portion.

The protrusion is formed only in a direction toward the protrusion provided on the lower support, and at least two or more are formed in parallel.

It is preferable that the combined height of the upper support part and the lower support part is greater than the thickness of the solar cell module.

According to an embodiment of the present invention, since the intellectual material member can be easily coupled to the edge of the solar cell module and is easily separated, work efficiency can be improved.

The drawings attached to this specification show schematics for easy explanation of the invention. Therefore, the accompanying drawings may be different from the actual one.
1 shows a state in which a solar cell module is horizontally loaded using a support member of an embodiment.
2 and 3 are views showing the support member of an embodiment as viewed from above and below, respectively.
4 shows a state in which the support member 10 configured as described above is coupled to the solar cell module 100.
5 shows a state in which a solar cell module is loaded using a support member.

The examples described below are only a preferred form and do not represent all of the present invention. In particular, the embodiments made by selectively selecting and selecting each of the constituent elements described through the embodiments below, and combining them, also belong to the present invention because each constituent element has already been described.

In addition, embodiments of the present invention will be described in detail below with reference to the drawings. In the description, the same reference numerals are assigned to the same or substantial portions of the drawings, and the description is not repeated to avoid duplication of description.

Hereinafter, an embodiment of the present invention will be described with reference to the accompanying drawings.

1 shows a state in which a solar cell module is horizontally loaded using a support member of an embodiment.

As illustrated in FIG. 1, the solar cell module 100 is horizontally loaded using the support member 10 on a pallet, and the loaded solar cell module is moved to another place by lifting the pallet with a forklift.

The support member 10 is located at four corners of the solar cell module 100 to support the solar cell module 100, and the solar cell module 100 is subjected to a mechanical shock such as colliding with the stacked solar cell modules 100. Protect

When the solar cell module is horizontally loaded, the load applied to the support member 10 corresponds to 20 kg times the number of modules loaded, and in general, a vertical load is applied to the support member 10.

Therefore, it is preferable that the support member 10 is made in a form that is easy to remove and attach while withstanding a vertical load.

2 and 3 are views showing the support member of an embodiment as viewed from above and below, respectively.

As illustrated in FIGS. 2 and 3, the support member 10 of this embodiment includes the upper support 12, the lower support 13, and the lower support 13, centering on the panel 11 having a flat bottom. It is configured to include a facing portion 14 facing.

The upper support part 12 protrudes upward from one end of the panel part 11 to form a wall, and has an approximately'a' shape to support the corner of the solar cell module 100. This upper support 12 is configured to include a coupling groove (12a). The coupling groove 12a is a groove formed in the upper support portion 12, and is coupled to the protrusion 13a formed in the lower support portion 13 in a male and female form. The coupling groove (12a) is formed by cutting a part of the upper support portion (12), and accordingly, the upper support portion (12) has the shape of the upper jaw due to the coupling groove (12a).

The lower support part 13, similar to the upper support part 12, protrudes downward from where the upper support part 12 is formed to form a wall with the upper support part 12, and supports the corner of the solar cell module 100. It has a roughly'a' shape so that you can do it. The lower support part 13 includes a coupling groove 12a and a protrusion 13a coupled in a male and female form in the same line as the position where the coupling groove 12a is formed, and the depth and the protrusion 13a of the coupling groove 12a ) Has the same height. The lower support part 13 also has a lower jaw due to the protrusion 13a.

The facing portion 14 is at one end of the lower portion of the panel portion 11 and is located away from the lower support portion 13, and is formed in a shape facing the lower support portion 13 by protruding downward from there. Accordingly, a guide groove 19 in a'b' shape is formed in the lower portion of the panel portion 11 for the facing portion 14 and the lower support portion 13.

The lower surface of the panel 11 is a place where the facing portion 14 and the panel 11 meet, and a plurality of straight-shaped protrusions 11a are formed only in the horizontal direction. The height of the protrusion 11a is lower than the height of the facing portion 14. In the drawing, it is illustrated that four protrusions 11a are formed apart from neighboring ones at regular intervals.

The latch 15 is formed at one end of the facing portion 14 in a direction in which the protrusion 11a is not formed.

The support member 10 having such a configuration is made by injection molding a resin such as ABS (acrylonitrile-butadiene-styrene resin) or PC (polycarbonate resin).

4 shows a state in which the support member 10 configured as described above is coupled to the solar cell module 100, and FIG. 5 shows a state in which the solar cell module is loaded using the support member.

As shown, the support member 100 is coupled to the edge of the frame 110, and there is a guide groove 19 made by the lower support part 13 and the face part 14, so that the support member 11 is easy and simple. It is coupled to the edge of the frame 110.

Meanwhile, the frame 110 includes a vertical frame 110a and a horizontal frame 110b, which are fastened to each other with screws. For example, assuming that screws are fastened in the longitudinal direction of the vertical frame 110a in the horizontal frame 110b, the frame is structurally vulnerable to stress transmitted in the longitudinal direction of the vertical frame 110a. Therefore, it should be prevented from moving in the longitudinal direction of the vertical frame 110a, and the support member 100 of this embodiment is positioned in a state in which the coupling groove 12a and the protrusion 13a are coupled toward the vertical frame 110a. It is possible to prevent the module from moving in the length direction of (110a).

In addition, since the vertical frame 110a includes a step, the height of the surface varies depending on the position. However, the support member 10 of this embodiment includes a protrusion 11a, so that the support member 10 can be fixed according to the step of the vertical frame 110a, and the solar cell module 100 is loaded. It is possible to limit the movement in the left and right directions (see FIG. 4).

And, even when the support member 10 is coupled to the horizontal frame (110b), there is a guide groove (19) made by the lower support portion (13) and the facing portion (14), so that the support member 10 is easy and simple. ) Is joined to the corner. In addition, since the latch 15 provided at the end of the facing portion 14 is fastened to the frame 100 in a clasp shape, when the support member 10 is coupled to the horizontal frame 110b, movement in the vertical direction can be restricted. Yes (see Fig. 5).

As a result, the support member 10 can be simply installed in a form in which the top, bottom, left and right are fixed due to the protrusion 11a and the latch 15, and disassembly of the support member 10 can also be simplified.

As shown in FIG. 5, the support member 10 is coupled to the edge between the solar cell module and the module in a plug-in manner.

The support member 10 located on the second layer is coupled with the support member 10 located on the first layer, and the protrusion 13a provided on the support member 10 of the second layer is the support member of the first layer. It is coupled in the form of being mounted on the coupling groove 12a provided in the upper support 12. In this embodiment, since the support members of the first layer and the second layer are combined as described above, there is an advantage of easy loading and dismantling.

In this embodiment, the solar cell module 100 is wrapped in the upper support portion 12 and the lower support portion 13 of the support member 10 located in different layers, the self-load of the solar cell module 100 Because of this, it is possible to securely fix the support member even in the form of simply mounting.

Preferably, the combined height of the upper support portion 12 and the lower support portion 13 is larger than the thickness of the solar cell module, and is configured to sufficiently support the solar cell module.

Claims (8)

A panel portion supporting the edge of the solar cell module,
An upper support part protruding upward from the panel part in a'L' shape to form a wall, and having a coupling groove made by cutting a part,
A lower support part protruding downward from the panel part to form a wall like the upper support part and having a protrusion placed in the coupling groove,
A facing portion facing the lower support portion and forming a'L' shaped guide groove under the panel portion,
Including,
Solar cell module mounting support member further comprising a protrusion protruding from the facing portion toward the lower support portion.
The method of claim 1,
A supporting member for mounting a solar cell module having the same depth as the height of the protrusion.
The method of claim 1,
The supporting member for mounting a solar cell module further comprises a latch coupled to the frame of the solar cell module in the form of a latch on the facing portion.
The method of claim 3,
The latch is a support member for mounting a solar cell module formed at the end of the facing portion.
delete The method of claim 1,
The supporting member for mounting a solar cell module, wherein the protrusion is formed only in a direction toward the protrusion provided on the lower support.
The method of claim 1,
A supporting member for mounting a solar cell module in which at least two or more of the protrusions are formed in parallel.
The method of claim 1,
A supporting member for mounting a solar cell module having a combined height of the upper and lower support portions greater than a thickness of the solar cell module.

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